链霉菌酪氨酸酶基因的克隆与表达

本文综述了近年来对链霉菌酪氨酸酶基因的研究。由酪氨酸酶合成黑色素是链霉菌属各个种的共同特性,并受到酪氨酸酶基因的控制。链霉菌几个种的酪氨酸酶基因已克隆到,其产黑色素的特性使之作为重要的标记基因得以广泛应用,同时,该基因在链霉菌的不同种及不同属的微生物中得到了高水平的表达。链霉菌酪氨酸酶基因表达调控的分子机制也得到较深入的研究。     

Bacterial tyrosinases

Tyrosinases are nearly ubiquitously distributed in all domains of life. They are essential for pigmentation and are important factors in wound healing and primary immune response. Their active site is characterized by a pair of antiferromagnetically coupled copper ions, CuA and CuB, which are coordinated by six histidine residues. Such a "type 3 copper centre" is the common feature of tyrosinases, catecholoxidases and haemocycanins. It is also one of several other copper types found in the multi-copper oxidases (ascorbate oxidase, laccase). The copper pair of tyrosinases binds one molecule of atmospheric oxygen to catalyse two different kinds of enzymatic reactions: (1) the ortho-hydroxylation of monophenols (cresolase activity) and (2) the oxidation of o-diphenols to o-diquinones (catecholase activity). The best-known function is the formation of melanins from L-tyrosine via L-dihydroxyphenylalanine (L-dopa). The complicated hydroxylation mechanism at the active centre is still not completely understood, because nothing is known about their tertiary structure. One main reason for this deficit is that hitherto tyrosinases from eukaryotic sources could not be isolated in sufficient quantities and purities for detailed structural studies. This is not the case for prokaryotic tyrosinases from different Streptomyces species, having been intensively characterized genetically and spectroscopically for decades. The Streptomyces tyrosinases are non-modified monomeric proteins with a low molecular mass of ca. 30kDa. They are secreted to the surrounding medium, where they are involved in extracellular melanin production. In the species Streptomyces, the tyrosinase gene is part of the melC operon. Next to the tyrosinase gene (melC2), this operon contains an additional ORF called melC1, which is essential for the correct expression of the enzyme. This review summarizes the present knowledge of bacterial tyrosinases, which are promising models in order to get more insights in structure, enzymatic reactions and functions of "type 3 copper" proteins in general.     

Copper transfer and activation of the Streptomyces apotyrosinase are mediated through a complex formation between apotyrosinase and its trans-activator MelC1.

The melanin operon (melC) of Streptomyces antibioticus is composed of two genes that encode MelC1 and MelC2 proteins. MelC1 has been suggested as a trans-activator which can facilitate the incorporation of copper into the apotyrosinase (MelC2) (Lee, Y.-H. W., Chen, B.-F., Wu, S.-Y., Leu, W.-M., Lin, J.-J., Chen, C. W., and Lo, S. J. (1988) Gene (Amst.) 65, 71-81). However, the molecular mechanism of the trans-activation or copper-transfer process mediated through MelC1 to MelC2 is not clear yet. In this study, we found apotyrosinase in both the extracellular fraction and cell extract from cells grown in copper-deficient medium. Using gel-filtration and immunoaffinity chromatographies, we demonstrated that apotyrosinase (MelC2) formed a stable complex with MelC1 in the intra- and extracellular fractions. Furthermore, addition of copper ion to the complex generated tyrosinase activity. The MelC1-MelC2 complex was purified to near homogeneity by DE52 and phenyl-agarose chromatographies. In conjunction with fast protein liquid gel filtration chromatography and NH2-terminal sequencing analysis, the results indicated that the stoichiometric ratio of MelC1 and MelC2 in the purified complex was 1:1. Essentially no copper was found in the complex. Addition of copper ion to the purified complex resulted in incorporation of approximately 2 molecules of copper ion and the mature active tyrosinase was gradually released from the complex. Taken together, these results demonstrate that the molecular mechanism of activation of Streptomyces apotyrosinase by its trans-activator MelC1 is initially mediated via a binary complex formation between these two proteins, followed by incorporation of copper ion. This activation mechanism accounts for the essential role of MelC1 in the expression of melanin operon.     

Secretion of the Streptomyces tyrosinase is mediated through its trans-activator protein, MelC1.

The tyrosinase of Streptomyces antibioticus is encoded by the second open reading frame, melC2 of the melanin operon (melC). The upstream open reading frame melC1 specifies a 146-amino acid protein with a typical NH2-terminal signal-peptide characteristic of a secretory protein. The MelC1 protein is involved in the transfer of copper ion to apotyrosinase MelC2 via binary complex formation (Lee, Y.-H. W., Chen, B.-F., Wu, S.-Y., Leu, W.-M., Lin, J.-J., Chen, C. W., and Lo, S. J. (1988) Gene (Amst.) 65, 71-81; Chen, L.-Y., Leu, W.-M., Wang, K.-T., and Lee, Y.-H.W. (1992) J. Biol. Chem. 267, 20100-20107). To investigate whether the export of tyrosinase is also dependent on MelC1, a mutational study of its signal-peptide sequence was performed. Four different mutants were obtained. Mutation at the positively charged region (mutant M-6LE, Arg6-Arg7----Leu6-Glu7) or the hydrophobic region (mutant M-16D, Val16----Asp16) led to Mel- phenotypes. These lesions caused a severe 7-10-fold reduction of the export of both the MelC1 and MelC2 proteins and a concomitant accumulation of the two proteins in the cytosolic fraction. The cell-associated tyrosinase activity in M-6LE but not in the M-16D mutant was dramatically reduced to 4% of the activity found in the wild type strain, suggesting that the basic NH2 terminus of MelC1 is also important for the trans-activation function of this protein. Nevertheless, the defects on the trans-activation and/or secretory functions of MelC1 in mutants M-6LE and M-16D are not due to the impairment of the formation of the MelC1.MelC2 complex. The translation of melanin operon genes in these two mutants also decreased. In contrast, the tyrosinase activity and the secretion of MelC2 were not affected if the mutations occurred at the putative cleavage site of the signal peptidase (e.g. mutant M-29SM, Arg29-Ala30----Ser29-Met30 or mutant 29-SMG, Arg29-Ala30-Asp31----Ser29-Med30-Gly31+ ++). Additionally, tyrosinase activity and its export were abolished in a MelC1-negative mutant, M-950. Taken together, these results demonstrate that a functional MelC1 is essential for tyrosinase secretion and activity. Furthermore, the results suggest that like other secretory proteins, basic and hydrophobic residues in the MelC1 signal sequence are an important feature of the signal-peptide and play a pivotal role in the secretion of both the MelC1 and MelC2 proteins.(ABSTRACT TRUNCATED AT 400 WORDS)     

Calculating molar absorptivities for quinones: application to the measurement of tyrosinase activity

The molar absorptivities of the quinones produced from different o-diphenols, triphenols, and flavonoids were calculated by generating the respective quinones through oxidation with an excess of periodate. Oxidation of these substrates by this reagent was analogous to oxidation by tyrosinase with molecular oxygen, although the procedure showed several advantages over the enzymatic method in that oxidation took place almost immediately and quinone stability was favored because no substrate remained. The o-diphenols studied were pyrocatechol, 4-methylcatechol, 4-tert-butylcatechol, 3,4-dihydroxyphenylalanine, 3,4-dihydroxyphenylethylamine, 3,4-dihydroxyphenylacetic acid, 3,4-dihydroxyphenylpropionic acid, and caffeic acid; the triphenols studied were pyrogallol, 1,2,4-benzenetriol, 6-hydroxydopa, and 6-hydroxydopamine; and the flavonoids studied were (+)catechin, (-)epicatechin, and quercetin. In addition, the stability of the quinones generated by oxidation of the compounds by [periodate]0/[substrate]0 < 1 was studied. Taking the findings into account, tyrosinase could be measured by following o-quinone formation in rapid kinetic studies using the stopped-flow method. However, measuring o-quinone formation could not be useful for steady-state studies. Therefore, several methods for following tyrosinase activity are proposed, and a kinetic characterization of the enzyme's action on these substrates is made.     

Redox reaction between amino-(3,4-dihydroxyphenyl)methyl phosphonic acid and dopaquinone is responsible for the apparent inhibitory effect on tyrosinase.

Amino-(3,4-dihydroxyphenyl)methyl phosphonic acid, the phosphonic analog of 3,4-dihydroxyphenylglycine, had been previously reported as a potent inhibitor of tyrosinase. The mechanism of the apparent enzyme inhibition by this compound has now been established. Amino-(3,4-dihydroxyphenyl)methyl phosphonic acid turned out to be a substrate and was oxidized to o-quinone, which evolved to a final product identified as 3,4-dihydroxybenzaldehyde, the same as for 3,4-dihydroxyphenylglycine. Monohydroxylated compounds (amino-(3-hydroxyphenyl)methyl phosphonic acid and amino-(4-hydroxyphenyl)methyl phosphonic acid) were not oxidized, neither was 4-hydroxy-l-phenylglycine. However, the relatively high Km for amino-(3,4-dihydroxyphenyl)methyl phosphonic acid (0.52 mm) indicated that competitive inhibition could not entirely explain the previously reported strong inhibitory effect (Ki = 50 and 97 micro m for tyrosine and 3-(3,4-dihydroxyphenyl)alanine (Dopa) as substrates, respectively). Neither was the enzyme covalently inactivated to a significant degree. Spectroscopic and electrochemical analysis of the oxidation of a mixture of Dopa and the inhibitor demonstrated that the phosphonic compound reduced dopaquinone back to Dopa, thus diminishing and delaying the formation of dopachrome. This produces an apparent strong inhibitory effect when the reaction is monitored spectrophotometrically at 475 nm. In this peculiar case Dopa acts as a redox shuttle mediating the oxidation of the shorter phosphonic homolog. Decomposition of the phosphonic o-quinone to 3,4-dihydroxybenzaldehyde drives the reaction against the slightly unfavorable difference in redox potentials.     

Catalytic properties of an organic solvent-resistant tyrosinase from Streptomyces sp. REN-21 and its high-level production in E. coli

An organic solvent-resistant tyrosinase (OSRT) from Streptomyces sp. REN-21 is a unique enzyme showing high activity in the presence of organic solvents. The OSRT-catalyzed oxidation of monophenols such as tyrosine-containing peptides and proteins was examined. The catalytic properties of OSRT were compared with those of mushroom tyrosinase. OSRT was shown to oxidize Gly-l-Tyr most effectively among four peptide substrates tested. On the other hand, mushroom tyrosinase showed the highest activity toward l-Tyr-Gly under the condition of 1 mM substrate. OSRT oxidized several proteins, including casein and hemoglobin, with relatively higher activity compared with mushroom tyrosinase under the condition of 1% (w/v) substrate. Thus, it was clarified that the catalytic properties of OSRT toward tyrosine-containing peptides and proteins are different from those of mushroom tyrosinase under these conditions. The OSRT-encoding gene operon was cloned, and found to consist of two genes, designated ORF-OSRT and ORF-393. The former encodes apo-OSRT, and the latter encodes the putative activator protein of apo-OSRT. A binuclear copper-binding site (type-3 copper site) characteristic of tyrosinases is contained in the deduced amino acid sequence for apo-OSRT. A high-level production system for the OSRT was constructed using pET20b(+) and Escherichia coli BL21(DE3)pLysS. Approximately 54 mg of active OSRT was synthesized in a 1-liter broth culture by this system. The properties of the recombinant OSRT were similar to those of the wild-type enzyme. In conclusion, we succeeded in constructing a high-level production system for OSRT.     

A cloned ompR-like gene of Streptomyces lividans 66 suppresses defective melC1, a putative copper-transfer gene

Expression of tyrosinase in Streptomyces requires functional MelC1 protein, which is postulated to transfer copper to apotyrosinase. We have previously isolated a mutant of Streptomyces lividans, HT32, that phenotypically suppressed mutations in cloned melC1 (H.-C. Tseng and C. W. Chen, in preparation). Plasmid pLUS132, containing an ATG to ATA transition at the initiation codon of melC1, was used for cloning the suppressor gene from HT32. A 1687 bp suppressor DNA was isolated that contained two characteristic Streptomyces coding sequences: a 217-amino-acid open reading frame (cutR) and a truncated open reading frame (cutS) downstream. Subcloning analysis attributed the phenotypic suppression activity to the putative cutR gene from HT32. The putative CutR exhibited similarity to the response regulator OmpR of the osmoregulatory signal-transduction system in Escherichia coli. The truncated CutS resembled, to a lesser degree, the N-terminus of EnvZ, the histidine protein kinase counterpart of OmpR. DNA hybridizing to the cloned cutR-cutS sequence was detected in 16 other Streptomyces species. We postulate that the putative cutR-cutS operon regulates copper metabolism in Streptomyces.     

Cloning and molecular characterization of a SDS-activated tyrosinase from Marinomonas mediterranea

The sequence of the tyrosinase gene cloned from Marinomonas mediterranea is reported. It is the second tyrosinase cloned from a Gram negative bacterium. Its size is higher than that of Gram positive tyrosinases from Streptomyces, and more similar to the eukaryotic enzymes. Its sequence shares the features of copper-binding sites found in all tyrosinases. Based in the comparison of tyrosinases from all types of organisms, an extension of the characteristic signatures existing at Prosite is proposed. This tyrosinase shares with some plant and amphibian tyrosinases a strong specific activation by submicellar concentrations of SDS. Intrinsic fluorescence and kinetic properties indicate that the activation is caused by an SDS-dependent conformational change that facilitates the substrate accessibility to the dicopper active site.     

The crystal structure of an extracellular catechol oxidase from the ascomycete fungus Aspergillus oryzae

Catechol oxidases (EC 1.10.3.1) catalyse the oxidation of o-diphenols to their corresponding o-quinones. These oxidases contain two copper ions (CuA and CuB) within the so-called coupled type 3 copper site as found in tyrosinases (EC 1.14.18.1) and haemocyanins. The crystal structures of a limited number of bacterial and fungal tyrosinases and plant catechol oxidases have been solved. In this study, we present the first crystal structure of a fungal catechol oxidase from Aspergillus oryzae (AoCO4) at 2.5-Å resolution. AoCO4 belongs to the newly discovered family of short-tyrosinases, which are distinct from other tyrosinases and catechol oxidases because of their lack of the conserved C-terminal domain and differences in the histidine pattern for CuA. The sequence identity of AoCO4 with other structurally known enzymes is low (less than 30 %), and the crystal structure of AoCO4 diverges from that of enzymes belonging to the conventional tyrosinase family in several ways, particularly around the central α-helical core region. A diatomic oxygen moiety was identified as a bridging molecule between the two copper ions CuA and CuB separated by a distance of 4.2–4.3 Å. The UV/vis absorption spectrum of AoCO4 exhibits a distinct maximum of absorbance at 350 nm, which has been reported to be typical of the oxy form of type 3 copper enzymes.     

Novel benzene ring biosynthesis from C(3) and C(4) primary metabolites by two enzymes

The shikimate pathway, including seven enzymatic steps for production of chorismate via shikimate from phosphoenolpyruvate and erythrose-4-phosphate, is common in various organisms for the biosynthesis of not only aromatic amino acids but also most biogenic benzene derivatives. 3-Amino-4-hydroxybenzoic acid (3,4-AHBA) is a benzene derivative serving as a precursor for several secondary metabolites produced by Streptomyces, including grixazone produced by Streptomyces griseus. Our study on the biosynthesis pathway of grixazone led to identification of the biosynthesis pathway of 3,4-AHBA from two primary metabolites. Two genes, griI and griH, within the grixazone biosynthesis gene cluster were found to be responsible for the biosynthesis of 3,4-AHBA; the two genes conferred the in vivo production of 3,4-AHBA even on Escherichia coli. In vitro analysis showed that GriI catalyzed aldol condensation between two primary metabolites, l-aspartate-4-semialdehyde and dihydroxyacetone phosphate, to form a 7-carbon product, 2-amino-4,5-dihydroxy-6-one-heptanoic acid-7-phosphate, which was subsequently converted to 3,4-AHBA by GriH. The latter reaction required Mn(2+) ion but not any cofactors involved in reduction or oxidation. This pathway is independent of the shikimate pathway, representing a novel, simple enzyme system responsible for the synthesis of a benzene ring from the C(3) and C(4) primary metabolites.     

Oxidation of 3,4-dihydroxymandelic acid catalyzed by tyrosinase

Tyrosinase usually catalyzes the conversion of monophenols to o-diphenols and the oxidation of o-diphenols to the corresponding quinones. However, when 3,4-dihydroxymandelic acid was provided as the substrate, 3,4-dihydroxybenzaldehyde was produced. These results led to the proposal that tyrosinase catalyzes an unusual oxidative decarboxylation of this substrate (Sugumaran, M. (1986) Biochemistry 25, 4489-4492). However, 3,4-dihydroxybenzaldehyde is also obtained through the oxidation of 3,4-dihydroxymandelic acid by sodium periodate and on a mercury electrode. These results led to the proposal that tyrosinase catalyzes the oxidation of the substrate into o-quinone, which reacts immediately with a molecule of substrate, oxidizing it and through decarboxylation generates an intermediate (quinone methide) which transforms into 3,4-dihydroxybenzaldehyde; simultaneously, the original o-quinone is reduced to 3,4-dihydroxymandelic acid.     

Oxidation products of quercetin catalyzed by mushroom tyrosinase

Quercetin was oxidized as a substrate catalyzed by mushroom tyrosinase to the corresponding o-quinone and subsequent isomerization to p-quinone methide type intermediate; followed by the addition of water on C-2 yielding a relatively stable intermediate, 2-(3,4-dihydroxybenzoyl)-2,4,6-trihydroxy-3(2H)-benzofuranone. In the presence of a catalytic amount of l-DOPA as a cofactor, the rate of this oxidation was enhanced. Fisetin, which lacks the C-5 hydroxyl group, was also oxidized but the rate of oxidation was faster than that of quercetin, indicating that the C-5 hydroxyl group is not essential but is associated with the activity.     

Structure–activity relationships of various amino-hydroxy-benzenesulfonic acids and sulfonamides as tyrosinase substrates

Background

o-Aminophenols have been long recognised as tyrosinase substrates. However their exact mode of interaction with the enzyme's active site is unclear. Properly vic-substituted o-aminophenols could help gain some insight into tyrosinase catalytic mechanism.

Methods

Eight vic-substituted o-aminophenols belonging to two isomeric series were systematically evaluated as tyrosinase substrates and/or activators and/or inhibitors, by means of spectrophotometric techniques and HPLC-MS analysis. Some relevant kinetic parameters have also been obtained.

Results

Four o-aminophenolic compounds derived from 3-hydroxyorthanilic acid (2-amino-3-hydroxybenzenesulfonic acid) and their four counterparts derived from the isomeric 2-hydroxymetanilic acid (3-amino-2-hydroxybenzenesulfonic acid) were synthesised and tested as putative substrates for mushroom tyrosinase. While the hydroxyorthanilic derivatives were quite inactive as both substrates and inhibitors, the hydroxymetanilic compounds on the contrary all acted as substrates for the enzyme, which oxidised them to the corresponding phenoxazinone derivatives.

General significance

Based on the available structures of the active sites of tyrosinases, the different affinities of the four metanilic derivatives for the enzyme, and their oxidation rates, we propose a new hypothesis regarding the interaction between o-aminophenols and the active site of tyrosinase that is in agreement with the obtained experimental results.     

Chalcones as potent tyrosinase inhibitors: the importance of a 2,4-substituted resorcinol moiety

Compounds, which inhibit tyrosinase, could be effective as depigmenting agents. We have introduced a group of mono-, di-, tri- and tetra-substituted hydroxychalcones as effective tyrosinase inhibitors, showing that the most important factor determining tyrosinase inhibition efficiency is the position of the hydroxyl group(s) rather their number. The aim of the present study was to investigate the contribution of the different functional groups of the tetrahydroxychalcones to their inhibitory potency, with a view to optimizing the design of whitening agents. Four tetrahydroxychalcones were evaluated, the commercially available Butein and other three were synthesized, and their inhibitory effect on tyrosinase was tested. Results showed that a 2,4-substituted resorcinol subunit on ring B contributed the most to inhibitory potency. Changing the resorcinol substitute to position 3,5- or placing it on ring A significantly diminished the inhibitory effect of the compounds. A catechol subunit on ring A acted as a metal chelator (in the presence of copper ions) and as a competitive inhibitor (in the presence of tyrosinase), while a catechol on ring B oxidized to o-quinone (in the presence of both copper ions and tyrosinase). Three of the compounds also demonstrated antioxidant activity, which may contribute to the prevention of pigmentation. An examination of correlations between inhibitory activity and physical properties of the chalcones tested (such as dissociation energy and molecular planarity) showed positive correlation with the moment dipole value in the Y-axis, which may be used as an indicator of the inhibitory potential of new molecules. The present study revealed two very active tyrosinase inhibitors, 2,4,3',4'-hydroxychalcone and 2,4,2',4'-hydroxychalcone (with IC50 of 0.2 and 0.02 microM, respectively). Structure-related activity studies added some understanding of the role and contribution of different functional groups associated with tyrosinase inhibitors.     

Effect of captopril on mushroom tyrosinase activity in vitro

The study presented here demonstrates that the antihypertensive drug captopril ([2S]-N-[3-mercapto-2-methylpropionyl]-L-proline) is an irreversible non-competitive inhibitor and an irreversible competitive inhibitor of the monophenolase and diphenolase activities of mushroom tyrosinase when L-tyrosine and L-DOPA were assayed spectrophotometrically in vitro, respectively. Captopril was rendered unstable by tyrosinase catalysis because of the interaction between the enzymatic-generated product (o-quinone) and captopril to give rise to a colourless conjugate. Therefore, captopril was able to prevent melanin formation. The spectrophotometric recordings of the inhibition of tyrosinase by captopril were characterised by the presence of a lag period prior to the attainment of an inhibited steady state rate. The lag period corresponded to the time in which captopril was reacting with the enzymatically generated o-quinone. Increasing captopril concentrations provoked longer lag periods as well as a concomitant decrease in the tyrosinase activity. Both lag period and steady state rate were dependent of captopril, substrate and tyrosinase concentrations. The inhibition of both monophenolase and diphenolase activities of tyrosinase by captopril showed positive kinetic co-operativity which arose from the protection of both substrate and o-quinone against inhibition by captopril. Inhibition experiments carried out using a latent mushroom tyrosinase demonstrated that captopril only bound the enzyme at its active site. The presence of copper ions only partially prevented but not reverted mushroom tyrosinase inhibition. This could be due to the formation of both copper-captopril complex and disulphide interchange reactions between captopril and cysteine rich domains at the active site of the enzyme.     

Cloning and Molecular Characterization of a SDS‐Activated Tyrosinase from Marinomonas mediterranea

The sequence of the tyrosinase gene cloned from Marinomonas mediterranea is reported. It is the second tyrosinase cloned from a Gram negative bacterium. Its size is higher than that of Gram positive tyrosinases from Streptomyces, and more similar to the eukaryotic enzymes. Its sequence shares the features of copper‐binding sites found in all tyrosinases. Based in the comparison of tyrosinases from all types of organisms, an extension of the characteristic signatures existing at Prosite is proposed. This tyrosinase shares with some plant and amphibian tyrosinases a strong specific activation by submicellar concentrations of SDS. Intrinsic fluorescence and kinetic properties indicate that the activation is caused by an SDS‐dependent conformational change that facilitates the substrate accessibility to the dicopper active site.     

Liposome-entrapped tyrosinase: a tool to investigate the regulation of the Raper-Mason pathway

The effect of the entrapment of mushroom tyrosinase (EC 1.14.18.1) within liposomes on the enzyme activity and Km vs. L-3,4-dihydroxyphenylalanine is reported in the present work; the effect of cholesterol insertion within liposome membranes on the enzyme activity has also been studied. The oxidation rates of various monophenols and diphenols by free and liposome-integrated mushroom tyrosinase were measured and the oxidation latencies vs. different substrates investigated. The different substrates are apparently oxidized according to the properties of the substituents as electron donors or acceptors; the Km values vs. L-3,4-dihydroxyphenylalanine calculated on measuring O2 consumption are higher than those calculated on measuring the dopachrome production rates. It is interesting that natural substrates of tyrosinase are oxidized according to a negative catalysis by the liposome-entrapped enzyme; this point is discussed in relation to the well known cytotoxicity of some intermediates of the Raper-Mason pathway.